Vegetable Grafting Principles and Practices
Although the benefits of using grafted transplants are now fully recognized worldwide, the need to enlighten the scientific basis of rootstock-scion interactions under variable environmental pressures remains vital for extracting grafting-mediated crop improvement. This has prompted the COST (Europe...
| Otros Autores: | , , |
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Wallingford, UK :
CABI
2017.
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| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009746508106719 |
Tabla de Contenidos:
- 1: Introduction to vegetable grafting
- 1.1: Importance and use of vegetable grafting
- 1.2: The process of vegetable grafting
- 1.3: Problems associated with vegetable grafting
- 1.4: Conclusions 2: Genetic resources for rootstock breeding
- 2.1: Genetic diversity
- 2.2: Genebank collections
- 2.3: Current usage of genetic material in rootstocks
- 2.4: Germplasm collection of other plant families
- 2.5: Concluding remarks 3: Rootstock breeding: current practices and future technologies
- 3.1: Introduction
- 3.2: Stacking traits: meiosis or grafting or both?
- 3.3: Developing stable, core collections of germplasm for breeding
- 3.4: Deploying genetic diversity for rootstocks
- 3.5: Grafting as a tool for genetic hybridisation and chimera production
- 3.6: Selection of improved rootstocks
- 3.7: Transgenic rootstocks
- 3.8: Rootstock registration and commercialization 4: Rootstock-scion signalling: key factors mediating scion performance
- 4.1: Introduction
- 4.2: Current knowledge of ionic and chemical signalling between rootstock and scion
- 4.3: Conclusions 5: Physiological and molecular mechanisms underlying graft compatibility
- 5.1: Introduction
- 5.2: Anatomical and physiological steps during graft union development
- 5.3: Role of secondary metabolites at the interface in graft incompatibility
- 5.4: Cell-to-cell communication between graft partners
- 5.5: Understanding the molecular mechanisms involved in graft union formation and compatibility.
- 5.6: Methods for examining graft union development and compatibility
- 5.7: Conclusions and future perspectives 6: Grafting as agro-technology for reducing disease damage
- 6.1: Introduction
- 6.2: The first step: Managing diseases in the nursery
- 6.3: Disease spread from the nursery to the field, the example of powdery mildew of watermelons
- 6.4: Intra- and interspecific grafting and their relations to diseases
- 6.5: Biotic or abiotic stress? Different responses of grafted plants to environmental conditions, the case of "physiological wilt", and germplasm selection for rational breeding
- 6.6: Grafted plants' response to nematodes
- 6.7: Commercial rootstocks and unknown genetics
- 6.8: Different mechanisms involved in disease resistance induced by grafting
- 6.9: Conclusions 7: Grafting as a tool to tolerate abiotic stress
- 7.1: Introduction
- 7.2: Temperature stress
- 7.3: Salinity stress
- 7.4: Nutrient stress
- 7.5: Stress induced by heavy metals and metalloids
- 7.6: Stress by adverse soil pH
- 7.7: Drought and flood stress
- 7.8: Conclusions 8: Quality of grafted vegetables
- 8.1: What is quality?
- 8.2: Rootstock effects on fruit quality
- 8.3: Effects of grafting on ripening and postharvest behaviour
- 8.4: Bio-physiological processes affecting fruit quality
- 8.5: Conclusion and perspectives 9: Practical applications and speciality crops
- 9.1: Establishment of grafted transplant under Mediterranean climate conditions
- 9.2: Recommendations for the use of grafted plants in greenhouses. The case of the Netherlands
- 9.3: Role of grafting in speciality crops
- 9.4: Conclusions and future perspective of vegetable grafting
- 10: Index.
